KR20100058129A - Apparatus for gas pipe - Google Patents

Abstract

PURPOSE: A gas pipe apparatus is provided to constantly maintain the gas pressure inside a pipe by installing a pressure adjusting unit to adjust the gas pressure to a given pressure when gas flows through the pipe. CONSTITUTION: A gas pipe apparatus comprises a gas blocking part(A), a division port(130), a steam supply pipe(B), and a nitride supply pipe(120). The gas blocking part blocks gas provided to a pipe(110). The division port is connected to one end of the pipe. The division port divides the gas flowing along the pipe into a plurality of division pipes. The steam supply pipe is installed between the gas blocking portion and the division port. The steam supply pipe discharges the gas from the pipe and the division pipe to the outside of the pipe. The nitride supply pipe is installed between the steam supply pipe and the division port. The nitride gas supply pipe discharges the gas from the pipe and the division pipe to the outside of the pipe.

Description

Apparatus for gas pipe

The present invention relates to a gas piping device.

In general, by-product gas (Blast Furnace Gas, COKE OVEN GAS, and LADLE GAS) is generated in the operation process of the blast furnace, coke, steelmaking, etc. These by-product gas is supplied to the combustion facility of the steel mill to be used as fuel. Therefore, the pipe for receiving the by-product gas is installed in the combustion facility.

Hereinafter, referring to FIG. 1, a pipe 15 for supplying a by-product gas to the combustion facility 70 will be described.

The by-product gas is stored in the by-product gas holder 10 and then supplied to the combustion facility 70 through the gas pipe 15. On the other hand, the pipe 15 is worn or corroded by the dust, tar, various corrosive substances contained in the gas has a problem that the airtight maintenance is not made. Therefore, the pipe 15 performs periodic maintenance work. In order to maintain the pipe 15, first, the by-product gas supplied to the pipe 15 is shut off. In order to block the gas supplied to the pipe 15, the first blocking valve 20 is closed to block the gas supplied to the pipe 15. Thereafter, the gas flow rate adjusting valve 40, the second blocking valve 50, and the gas discharge valve 60 to remove the gas sealed in the pipe 15 between the first blocking valve 20 and the combustion equipment 70. ) To release the gas into the atmosphere.

However, if the first shut-off valve 20 is not completely sealed or the valve seat inside the first shut-off valve 20 is worn out while the closed gas is removed, the by-product gas continues to leak into the pipe 15. Mixed with air to form a mixed gas within the combustible range. In addition, when the maintenance work of the pipe 15 is performed while the by-product gas continues to leak into the pipe 15, an explosion accident may occur when an ignition source such as an electric spark comes into contact with the mixed gas.

Accordingly, the present invention is to improve the above problems, the gas to prevent the leakage of gas into the pipe during the maintenance process of the gas pipe, to effectively remove the residual gas remaining in the pipe, foreign gas contained in the foreign matter The purpose is to provide a plumbing device.

Another object of the present invention is to provide a gas piping device that prevents the pressure of the gas from rising above a predetermined pressure when the gas is supplied to the gas pipe.

Gas piping device according to an embodiment of the present invention in order to achieve the above object is a gas blocker for blocking the gas supplied to the pipe; A splitting port connected to one end of the pipe to divide the gas flowing along the pipe into a plurality of split pipes; A steam supply pipe installed between the gas blocking unit and the split port to discharge the gas sealed in the pipe and the split pipe to the outside of the pipe; And a nitrogen gas supply pipe installed between the steam supply pipe and the split port to discharge the gas sealed in the pipe and the split pipe to the outside of the pipe.

The foreign matter removing unit of claim 1, wherein the divided pipe may further include a foreign matter removing unit for removing a foreign matter contained in the gas flowing along the divided pipe, and the foreign matter removing unit includes a foreign matter contained in the gas flowing along the divided pipe. A discharge pipe for discharging; A port connected to the discharge pipe; A supply valve connected to the port and supplying water into the port; And a second drain pipe connected to the supply side to discharge material stored in the port to the outside.

In addition, the gas blocking unit supply side for supplying water to the curved pipe formed between the first and second blocking sides; A discharge pipe discharging water introduced into the curved pipe at a lower surface of the curved pipe; A port connected to the discharge pipe; And it may include a drain pipe for discharging the water stored in the port to the outside.

In addition, a pipe header may be installed at one end of the divided pipe separated by the split port.

In addition, a pressure control unit for measuring the pressure of the gas flowing along the pipe and the split pipe may be further installed on the pipe and the pipe header upper surface, wherein the pressure control unit is connected to the split port and the pipe header upper surface Third port; A port cover coupled to a flange formed on an outer circumferential surface of the third port; An opening hole formed along upper and lower surfaces and installed in the port cover; A fifth port sealed by an upper cover and having a body portion inscribed on an inner circumferential surface of the fourth port and floating by a pressure of a gas flowing along the fourth port; And a departure prevention member for preventing the fifth port from being separated from the fourth port. In addition, the separation prevention gas pipe is further provided with a center for adjusting the floating height of the fifth port.

In addition, the steam supply pipe and the nitrogen gas supply pipe may be selectively driven to discharge the gas sealed in the pipe and the split pipe to the outside of the pipe.

As described above, the gas piping device provided in the present invention can prevent the leakage of gas when the maintenance work of the pipe is in progress, it is possible to remove the foreign matter contained in the residual gas. In addition, the present invention is further provided with a pressure regulator for adjusting the pressure of the gas to a predetermined pressure when the gas flows along the pipe, it is possible to maintain a constant pressure of the gas flowing along the pipe.

Hereinafter, with reference to the drawings showing an embodiment of the present invention will be described in detail the structure of according to the present invention.

2 is a perspective view schematically showing a gas piping device according to the present invention, FIG. 3 is an enlarged view of a gas shutoff part according to the present invention, FIG. 4 is an enlarged view of a steam supply pipe according to the present invention, and FIG. 6 is an enlarged view of a pipe header, and FIG. 6 is an enlarged view of a foreign material removing unit according to the present invention.

In general, the gas flows into the pipe 110 and may be worn and corroded after years of use. In addition, dust, tar, and various corrosive substances may be deposited in the pipe 110. Therefore, the pipe 110 is performed periodic maintenance work.

In order to perform the maintenance work, first, the gas flowing in the pipe 110 is shut off, and the gas remaining in the pipe 110 is discharged to the atmosphere.

Accordingly, the pipe 110 is connected to one end of the pipe 110 and the gas blocker A for filling the pipe of the predetermined area to block the flow of by-product gas, and divides the pipe 110 into a plurality of pipes. To remove the foreign substances contained in the by-product gas flowing along the steam supply pipe (B) and nitrogen gas supply pipe 120, the pipe 110 for discharging the by-product gas remaining in the split port 130, the pipe 110 to the atmosphere To remove the foreign matter (C) is installed.

Referring to FIG. 3, the gas blocking unit A is installed between the first blocking side 111 and the second blocking side 112 to block the supply of by-product gas flowing through the pipe 110. The gas blocking unit A includes water stored in the curved pipe 200, the first supply pipe 210 for supplying water to the curved pipe 200, and the curved pipe 200, and a floating gas mixed with water (water and The mixed suspended gas is hereinafter referred to as gas condensate), a first discharge pipe 220 for discharging the first discharge port 220, a first port 230 and a first port storing water and gas condensed water discharged through the first discharge pipe 220. The first drain pipe 240 connected to the 230 to discharge the water and gas condensed water stored in the first port 230, the first water collecting tank for storing the water and gas condensed water discharged to the first drain pipe 240 250.

The curved pipe 200 is formed by bending a pipe disposed between the first blocking side 111 and the second blocking side 112 in a 'U' or 'V' shape. In addition, one side of the curved pipe 200 is connected to the first supply pipe 210 for supplying water to the curved pipe 200. The first supply pipe 210 supplies water to the curved pipe 200 to block a flow of gas flowing in the curved pipe 200.

The first discharge pipe 220 for discharging water and gas condensed water is installed at the lower end of the curved pipe 200. In addition, the first discharge pipe 220 is formed with a valve 221 for controlling the flow of water and gas condensed water flowing in the first discharge pipe 220.

The first drain pipe 240 is installed on the upper surface of the first port 230 to discharge the water and the gas condensed water stored in the first port 230 to a predetermined level or more. The first drain pipe 240 is connected to the first port 230 to discharge water and gas condensed water stored in the first port 230 to the first water collecting tank 250. That is, one end of the first drain pipe 240 is installed to be connected to the first port 230, and the other end is disposed above the first water collecting tank 250. In addition, a valve 241 is formed in the first drain pipe 240 to regulate the flow of water and gas condensed water discharged to the first water collecting tank 250.

The first filling pipe 260 prevents the gas from being discharged to the first discharge pipe 220 when the gas is supplied again to the combustion facility 170 after the maintenance work. That is, the first filling pipe 260 supplies water to the first discharge pipe 220 to prevent the gas flowing in the curved pipe 200 from being discharged to the first port 230 along the first discharge pipe 220. .

The first fill pipe 260 is connected to the first discharge pipe 220. The valve 261 is formed in the first inlet pipe 260, and when the maintenance work of the pipe 110 is performed, the valve 261 is closed, and when the gas is supplied to the valve 110, the valve 261 is opened. That is, when maintenance work on the pipes 110 and 140 is performed, the valve 261 of the first inlet pipe 260 is closed to supply water and gas condensed water falling from the curved pipe 200 to the first port 230. When the gas supply operation is performed to the pipes 110 and 140, the valve 261 is opened to supply water to the first discharge pipe 220 so that the gas does not flow along the first discharge pipe 220.

Looking at the operation method of the gas blocking unit (A), first, the first blocking side 111 and the second blocking side 112 is closed. Thereafter, the valve 211 of the first supply valve 210 is opened to supply water to the curved pipe 200. When water is supplied to the curved pipe 200, the gas supplied to the pipe 110 is blocked by the head difference.

As such, when a water sealing operation is performed in which water flows through the curved pipe 200 to block the gas, the by-product gas remaining in the pipes 110 and 140 is removed. Here, the residual by-product gas refers to a gas sealed in the pipe 110 and the split pipe 140 disposed between the gas blocking unit A and the combustion facility 170.

In order to remove the residual by-product gas, the steam supply pipe B and the nitrogen supply pipe 120 are provided between the gas shutoff portion A and the second shutoff edge 112. By-product gas is discharged to the outside of the pipe (110, 140) by the steam supplied from the steam supply pipe (B) or nitrogen gas supplied from the nitrogen supply pipe (120). In addition, when removing the by-product gas, one of the steam supply pipe (B) and nitrogen supply pipe 120 may be selectively operated to minimize energy consumption.

4 and 5, the steam supply pipe B sets the pressure in the pipe 110 to a negative pressure to discharge the by-product gas remaining in the pipes 110 and 140 to the outside of the pipes 110 and 140. The steam supply pipe B is connected to the third drain pipe 210 protruding from the upper surface of the pipe 110. The third drain pipe 210 is a discharge port for discharging the residual by-product gas, the diameter of the center portion is formed larger than the diameter of the upper and lower portions. In addition, a valve 211 is formed below the third drain pipe 210 to control opening and closing of the by-product gas. The steam supply pipe (B) is connected to the central portion of the third drain pipe 210, the inlet is so that the steam (STEAM) supplied to the steam supply pipe (B) is discharged to the atmosphere along the outlet of the third drain pipe (210) It is installed to face the outlet of the third drain pipe (210). Accordingly, the steam supplied from the steam supply pipe B is discharged to the outside along the outlet of the third drain pipe 210. In addition, a valve 201 is formed in the steam supply pipe B to control opening and closing of steam.

Looking at the method for discharging the residual by-product gas to the air using the steam supply pipe (B), first, the fourth drain pipe 220 provided in the second shut-off side 112 and the pipe header 150 is opened. Thereafter, the steam is supplied to the third drain pipe 210 through the steam supply pipe B. When the steam is discharged into the atmosphere through the third drain pipe 210, the pressure in the pipe (110, 140) is formed to a negative pressure by the pressure difference. When the pressure in the pipes 110 and 140 is formed at a negative pressure, the by-product gas remaining in the pipes 110 and 140 is discharged into the atmosphere through the third drain pipe 210 due to the pressure difference, and through the fourth drain pipe 220. Oxygen suspended in the atmosphere flows into the pipe header 150. As described above, when the steam introduced from the steam supply pipe B is discharged to the outside through the third drain pipe 210, oxygen is diverted to the pressure difference via the fourth drain pipe 220 and the pipe 110 and the split pipe 140. The by-product gas remaining in the pipes 110 and 140 is discharged into the atmosphere. Accordingly, only oxygen remains in the pipe 110 and the split pipe 140.

The nitrogen supply pipe 120 is to remove the by-product gas by purging the pipe 110 and the split pipe 140 with nitrogen gas, and the nitrogen supply pipe 120 is disposed between the steam supply pipe B and the second shut-off side 112. It is installed in the pipe 110 disposed in the. The valve 121 is installed in the nitrogen supply pipe 120.

Looking at the method for discharging the residual by-product gas to the atmosphere using the nitrogen supply pipe 120, first, the valve 121 installed in the nitrogen supply pipe 120 and the valve 161 provided in the fifth drain pipe 160 are opened. . At this time, the valve 221 provided in the fourth drain pipe 220 is closed. When the valves 121 and 161 are opened, nitrogen gas is supplied to the pipe 110 through the nitrogen supply pipe 120. When nitrogen gas is supplied through the nitrogen supply pipe 120, the pipe 110 and the split pipe 140 are purged with nitrogen gas and the by-product gas is discharged into the atmosphere through the fifth drain pipe 160.

In addition, when operating the steam supply pipe (B) and the nitrogen supply pipe 120 to operate the foreign matter removal unit (C) to remove the foreign matter contained in the by-product gas.

Referring to FIG. 6, the foreign substance removing unit C is to remove foreign substances contained in the by-product gas and is installed on the bottom surface of the split pipe 140.

The foreign matter removing unit C is connected to the second discharge pipe 300 and the second discharge pipe 300 installed at the lower portion of the divided pipe 140, and the foreign matter contained in the by-product gas supplied from the divided pipe 140 (tar, A second supply side 320 for storing moisture and a second supply side 320 connected to an upper portion of the second port 310 to supply water to the second port 310, and a second supply side 320. It is connected to the second drain pipe 330 for discharging the foreign matter stored in the second port 310, and a second water collecting tank 340 for storing the material discharged to the second drain pipe 330.

The second discharge pipe 300 is connected to the lower surface of the split pipe 140 to discharge foreign substances contained in the by-product gas to the second port 310. In addition, the foreign substance removing unit C may remove the by-product gas flowing to the second port 310 along the second discharge pipe (300).

The second discharge pipe 300 is provided with a valve 301 to control the opening and closing of the material moved through the second discharge pipe (300).

The second port 310 stores the material supplied from the second discharge pipe 300, and may store foreign substances and by-product gas included in the by-product gas.

A second supply side 320 for supplying water into the second port 310 is connected to an upper surface of the second port 310. The second supply side 320 includes a first pipe 322 installed on the upper surface of the second port 310 and a second pipe 323 connected to the first pipe 322. In addition, a valve 321 is installed in the second pipe 323 to control opening and closing of water supplied to the second port 310. The valve 321 installed in the second pipe 323 is completely opened during maintenance work to supply water to the second port 310, and when gas is supplied to the combustion facility 170, a part of the valve 321 is opened. A small amount of water is supplied to the second port 310. The reason for continuously supplying water to the second port 310 when gas is supplied to the combustion facility 170 is that the gas flowing along the separation pipe 140 flows into the second water collecting tank 340 when the pressure of the gas is formed to be higher than the prescribed pressure. To prevent it from being discharged.

The second drain pipe 330 is connected to the central portion of the first pipe 322. The second drain pipe 330 is a pipe for discharging the stored matter stored in the second port 310 to the second water collecting tank 340, and the second drain pipe 330 is installed in parallel with the first pipe 322. And a fourth pipe 332 connecting the third pipe 331, the first pipe 322, and the third pipe 331.

In this case, the first pipe 322 installed in the second port 310 is used as a common pipe between the second supply side 320 and the second drain pipe 330. That is, when water is supplied from the second supply side 320, the first pipe 322 supplies water to the second port 310, and when the storage stored in the second port 310 is accumulated to a predetermined level or more. The storage is discharged to the second collection tank 340 through the first pipe 322, the fourth pipe 332 and the third pipe 331.

Looking at the operation method of the foreign substance removal unit (C), when the steam or nitrogen gas is supplied to the pipe 110 through the steam supply pipe (B) or nitrogen supply pipe 120 during the maintenance work of the pipe (110,140) second discharge pipe (300) Open the valve 301 installed in the. In addition, before the steam or nitrogen gas flows into the pipe 110, the valve 321 of the second supply pipe 320 is opened to store water in the second port 320. When steam or nitrogen gas flows along the division pipe 140 of the foreign substance removing unit C, foreign substances (moisture, tar) contained in the steam or gas (nitrogen gas, split gas) may cause the second port ( To 310). Then, to remove the foreign matter stored in the second port 320, the valve 301 installed in the second discharge pipe 300 is closed. At this time, the water is continuously supplied to the second port 320 through the second supply pipe 320, the water and foreign matters supplied to the second supply pipe 320 through the second drain pipe 330, the second water collecting tank 340 To be discharged.

When the maintenance work of the gas pipes 110 and 140 is completed by the above-described method, the by-product gas is supplied to the pipe 110 again. At this time, when the pressure of the gas flowing along the pipe (110, 140) rises above a predetermined pressure may damage the combustion equipment 170 and the pipe (110, 140).

Therefore, in the present embodiment, the pressure regulating unit (D) for measuring the pressure of the by-product gas on the split port 130 and the pipe header 150 to discharge the by-product gas into the atmosphere when the pressure of the by-product gas rises above a predetermined pressure. Install it. Hereinafter, the pressure adjusting unit D will be described with reference to FIGS. 7A, 7B, and 8. In addition, for convenience of description, the pressure regulator D describes the pressure regulator D formed on the split port 130.

The pressure regulator D is inscribed in the inner circumferential surface of the third port 400 installed on the split port 130, the fourth port 430, and the fourth port 430 installed on the third port 400. The fifth port 440 is suspended according to the pressure of the by-product gas.

The third port 400 is installed on the split port 130. A flange 410 is formed at an end of the third port 400, and a photo cover 420 having a fourth port 430 is disposed on the flange 410. At this time, a gasket 415 is installed between the flange 410 and the photo cover 420 to prevent the gas flowing along the pressure adjusting unit D from leaking. In addition, a hole is formed in the circumferential direction of the flange 410, the gasket 415, and the photo cover 420, and a nut 421 is inserted into the hole, and a bolt 422 is fastened to the nut 421 to form a third port. 400 and the fourth port 430 are coupled.

The photo cover 420 has a hole formed in the axial direction, and the fourth port 430 is installed on the outer circumferential surface of the hole. The fourth port 430 is composed of a cylinder whose upper and lower surfaces are opened, and a protruding ring having a diameter larger than the diameter of the cylinder at the upper end of the cylinder.

The fifth port 440 is disposed inwardly on the inner circumferential surface of the fourth port 430, and floats above the fourth port 430 according to the pressure of the by-product gas. The fifth port 440 includes a body portion inscribed on the inner circumferential surface of the fourth port 430 and a circular plate covering the upper surface of the body portion. At this time, the diameter of the circular plate is formed larger than the diameter of the body portion, it is possible to prevent the fifth port 440 is inserted into the fourth port 430. That is, the circular plate of the fifth port 440 is supported by the protruding ring of the fourth port 430, so that the entire area of the fifth port 440 moves downward through the opening hole 431 of the fourth port 430. Prevent it from falling. In addition, the body portion of the fifth port 440 is formed to be the same or smaller than the diameter of the opening hole 431 to be inscribed in the opening hole 431 of the fourth port 430. The fifth port 440 is suspended when the pressure of the floating gas flowing along the third port 400 and the fourth port 430 rises above a predetermined pressure. When the fifth port 440 is floating, a space is formed between the fourth port 430 and the fifth port 440 so that the floating gas is discharged to the space.

In addition, in order to prevent the fifth port 440 from being separated from the fourth port 430 when the fifth port 440 is floated, a departure preventing member is fixedly installed in the fifth port 440.

The departure preventing member is hingedly coupled to the second support 460 to the first support 450 installed on the photo cover 420, the third support 470 for fixing the second support 460 and the fifth port 440. ).

In addition, a plurality of weights 480 are inserted into one region of the second support 460 to limit the movement of the second support 460. That is, the weight 480 adjusts the number of inserts into the second support 460 so that the second support 460 is moved only when the by-product gas is set to a specific pressure or more. In addition, in the combustion facility 170, ignition and extinguishing are repeatedly performed, and an explosion accident may occur when the by-product gas is discharged in the vicinity of the combustion facility 170. Therefore, in the present embodiment, the number of weights 480 installed in the split port 130 is set smaller than the number of weights 480 installed in the pipe header 150, and the pressure regulating portion D provided in the split port 130 is provided. ), The by-product gas is emitted preferentially.

In addition, when gas is supplied to the pipe 110 again, the valve 261 of the first inlet pipe 260 is opened to supply water to the first discharge pipe 220. Accordingly, the gas flowing in the curved pipe 200 is prevented from being discharged to the first port 230 along the first discharge pipe 220. In addition, in the second pipe 323, a small amount of the valve 321 is opened to supply water to the second port 340. Accordingly, the gas flowing along the split pipe 140 is prevented from being discharged to the second water collecting tank 340 along the second drain pipe 330.

Although the technical spirit of the present invention has been described in detail according to the above-described preferred embodiment, it should be noted that the above-described embodiment is for the purpose of description and not of limitation. In addition, those skilled in the art will understand that various embodiments are possible within the scope of the technical idea of the present invention.

1 is a perspective view showing a gas piping device.

Figure 2 is a perspective view schematically showing a gas piping device according to the present invention.

3 is an enlarged view of a gas blocker according to the present invention.

4 is an enlarged view of a steam supply pipe according to the present invention;

5 is an enlarged view of a piping header according to the present invention.

Figure 6 is an enlarged view of the foreign material removing unit according to the present invention.

7a and 7b are enlarged views of the pressure regulator according to the present invention.

8 is an exploded perspective view of the pressure adjusting unit according to the present invention.

[Description of Reference Numerals]

110: pipe 120: nitrogen supply pipe

130: split port 140: split piping

150: pipe header 170: combustion equipment

A: gas shutoff part B: steam supply pipe

C: Foreign material removal part D: Pressure control part

Claims (9)

A gas blocking unit for cutting off the gas supplied to the pipe; A splitting port connected to one end of the pipe to divide the gas flowing along the pipe into a plurality of split pipes; A steam supply pipe installed between the gas blocking unit and the split port to discharge the gas sealed in the pipe and the split pipe to the outside of the pipe; And A nitrogen gas supply pipe installed between the steam supply pipe and the split port to discharge gas sealed in the pipe and the split pipe to the outside of the pipe; Gas piping device comprising a. The gas piping device of claim 1, wherein the divided pipe further includes a foreign material removing unit for removing a foreign material contained in the gas flowing along the divided pipe. The method of claim 2, The foreign material removing unit A discharge pipe for discharging foreign matter contained in the gas flowing along the split pipe; A port connected to the discharge pipe; A supply valve connected to the port and supplying water into the port; And A second drain pipe connected to the supply side to discharge the material stored in the port to the outside; Gas piping device comprising a. According to claim 1, The gas blocking unit A supply side supplying water to the curved pipe formed between the first and second blocking sides; A discharge pipe discharging water introduced into the curved pipe at a lower surface of the curved pipe; A port connected to the discharge pipe; And A drain pipe for discharging water stored in the port to the outside; Gas piping device comprising a. According to claim 1, A gas piping device, wherein a pipe header is provided at one end of the divided pipe separated by the split port. 6. The method of claim 5, And a pressure regulator for measuring pressure of the gas flowing along the pipe and the split pipe on an upper surface of the pipe and the pipe header. The method according to claim 6, The pressure control unit A third port connected to the split port and an upper surface of the pipe header; A port cover coupled to a flange formed on an outer circumferential surface of the third port; An opening hole formed along upper and lower surfaces and installed in the port cover; A fifth port sealed by an upper cover and having a body portion inscribed on an inner circumferential surface of the fourth port and floating by a pressure of a gas flowing along the fourth port; And And a release preventing member for preventing the fifth port from being separated from the fourth port. The gas piping device according to claim 7, wherein the separation prevention band is further provided with a center weight for adjusting the floating height of the fifth port. According to claim 1, The steam supply pipe and the nitrogen gas supply pipe is selectively driven to discharge the gas sealed in the pipe and the divided pipe to the outside of the pipe.

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